Method and apparatus for recovering data stream clock

ABSTRACT

A home network architecture has an internal digital network interconnecting devices in the home. Entertainment services are introduced into the network through network interface units that are coupled to an external network and to the internal network. The network interface units perform the necessary interfacing between the external and internal networks and perform MPEG clock recovery from an MPEG video data stream. To prevent jitter when the MPEG data stream is transmitted over the internal network to set-top electronics, the recovered MPEG clock is locked by the network interface unit to the internal network clock and then transmitted over the internal network. The set-top electronics then recovers the MPEG clock from the locked MPEG clock transmitted over the internal network. The video data may then be generated using the recovered MPEG clock and displayed on a television, for example.

RELATED APPLICATIONS

This patent application is related to U.S. application Ser. No. 08/561,7589, filed on Nov. 22, 1995, entitled HOME MULTIMEDIA NETWORK ARCHITECTURE; U.S. application Ser. No. 08/561,757, filed on Nov. 22, 1995, entitled SET-TOP ELECTRONICS AND NETWORK INTERFACE UNIT ARRANGEMENT; U.S. application Ser. No. 08/561,534, filed on Nov. 22, 1995, entitled CROSSBAR/HUB ARRANGEMENT FOR MULTIMEDIA NETWORK.

FIELD OF THE INVENTION

The present invention relates to multimedia digital networks, and more particularly, to the recovery and locking of the clock of a video data stream received at a digital home network for conversion for use or display by in-home products, such as televisions.

BACKGROUND OF THE INVENTION

The rapid gains in digital technology and telecommunications have increased the desirability of having a network in the home to interconnect a multitude of products in the home with each other and to the outside world. The range of available outside services includes interactive services, cable video and audio services, satellite networks, telephone company services, video on demand, and other types of information services. However, penetration of the personal computer into homes in the United States is approximately 33% and only growing slowly, although governments desire more extensive penetration to encourage “telecommuting” and reduce road traffic and pollution. Further penetration of computers in the home will originate from the purchase of consumer entertainment and informational products containing an embedded computer and operating system hidden by an opaque user interface. Such a product is a conventional set-top box.

Set-top boxes are multi-media computers that augment the use of televisions. A conventional set-top box has an external network interface module that connects the set-top box to the external network and data provider. The network interface module has to perform a number of sophisticated functions, such as interfacing to a specific external network, tuning, demodulation, error correcting, video descrambling, recovery of MPEG clock, and encryption and decryption specific to the external network. Consequently, the network interface module is a relatively expensive component of set-top boxes. This expense would be necessary even when a single television is present in the house. However, most homes contain multiple televisions, and providing each with its own set-top box and associated network interface module is a duplication of expensive components.

One of the functions of network interface units is Motion Pictures Experts Group (MPEG) clock recovery, MPEG-1 and MPEG-2 being different accepted standards for transmitting digitized video data. MPEG data is a continuous stream of data normally clocked at 27 MHz. In conventional arrangements, where the network interface unit is coupled by a bus to the set-top electronics, there is little or no danger of degradation of the video signal due to jitter, since a local bus will not introduce substantial jitter. In contrast, if the video data is placed onto a shared network and distributed through a hub, jitter is likely to be introduced by the home network since the video data may be buffered behind other data at certain points in the network. The higher the jitter, the more difficult it is to recover the clock at the set-top electronics as required.

In order to provide a relatively inexpensive home multimedia network, in which MPEG data is available to multiple set-top electronics coupled to the network, it is necessary to accurately recover the MPEG clock at the separate set-top electronics units.

SUMMARY OF THE INVENTION

The above described and other needs are met by the present invention which provides a method and apparatus for accurately recovering the MPEG clock from a stream of MPEG data. In certain embodiments, the MPEG clock is recovered first at a network interface unit coupled to an external network. A frequency synthesizer at the network interface unit locks the recovered MPEG clock to an internal network clock, such as an Ethernet clock. As an example, the MPEG clock may be 27 MHz, and the Ethernet clock may be 10 MHz. Thus, when packets of data are transmitted from the network interface unit to the set-top electronics, the packets are locked to the recovered MPEG clock at 27 MHz. At the set-top electronics end of the internal network another synthesizer regenerates the 27 MHz clock from the locked version of the clock that is sent with the data packets over the internal network.

The present invention provides the advantage of allowing transmission of MPEG video data over a relatively inexpensive home network, such as Ethernet, without incurring jitter. A further advantage of the present invention is that once the signal is locked to the recovered MPEG clock, it is easier and faster for any set-top electronics unit to lock onto the signal.

The foregoing and other features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic block diagram of a home network constructed in accordance with an exemplary embodiment of the present invention.

FIG. 2 is a depiction of an exemplary installation of the home network of the present invention within a home.

FIG. 3 is a logical diagram of the home network of FIG. 1.

FIG. 4 is a schematic depiction of a network interface unit and a set-top electronics unit constructed in accordance with preferred embodiments of the present invention.

FIG. 5 is a block diagram of a network interface of the set-top electronics constructed in accordance with an exemplary embodiment of the present invention.

FIG. 6 is a block diagram of the network interface of the network interface unit constructed in accordance with an embodiment of the present invention.

FIG. 7 is a block diagram of a hub and direct circuit crossbar, constructed in accordance with an embodiment of the present invention, coupled to a network interface unit and a set-top electronics unit.

FIG. 8 is a logical diagram of an exemplary user interface for the home network of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a schematic depiction of a home multimedia network 10 constructed in accordance with an embodiment of the present invention. This embodiment is exemplary only, however, as the network 10 may be configured in any of a number of different ways within the scope of the invention, and may include different devices coupled to the network 10. Additionally, the invention is not limited to networks located in homes, but is applicable to networks installed in other types of structures, such as offices, apartment buildings, etc. For purposes of illustration, however, the exemplary embodiment will be described in the context of a home installation.

The network 10 is a digital network that provides connectivity of different types of equipment to the world outside the home. This equipment can be, for example, analog television 12, digital television 14, digital VCR 16, digital camcorder 18, personal computers 20, audio equipment 22, printers 24, facsimile machines 26, and telephones 28, among others. In addition to connecting this equipment to the outside world, the network 10 also connects the digital video, digital audio, computer and telephone equipment together internally in the home. This unifies communication and control within the home, making the full power of the external network connections or internal data sources available to any terminal on the network 10.

Communication with the outside world is performed through a number of separate network interface units (NIU's) 32 and may be combined physically in an entrance unit 30, with each network interface unit 32 permitting a connection between a different external network and the home network 10. The different external networks may carry different types of signals. These may be, for example, broadcast signals (digital or mixed analog/digital) carried on hybrid fiber coax or cable. Other types of signals are ISDN, broadcast/digital satellite service, FTTC, FTTH, ADSL, and others. At least the following data types may be carried: compressed video, compressed audio, compressed internet WWW graphics and data, internet e-mail and other data, computer file data and control message data.

Logically all terminals in the home network 10 receive equal access to the network interface units 32 and a user would be unaware of the physical siting of them. The number of network interface units 32 that are required is determined by the number of streams required per home, e.g. the number of different program channels (i.e., video, audio, and other) required simultaneously, not by the number of terminal units in a home.

In certain preferred embodiments, cable or antenna television is retained unmodified with distribution by regular in-home coax (plain old television, or POTV). POTS (plain old telephone service) is also carried on the in-home digital network 10.

The digital signals are distributed throughout the home over an internal network 34. In certain preferred embodiments, the internal network 34 is essentially Ethernet of type 10base-T or 100base-T twisted pair but a special switch hub is employed to make the network scalable to any number of terminal units each able to receive high bit-rate video.

The home network 10 connects those computers, or products with embedded computers, that can support the networking bandwidth, protocols, routing, buffering and addressing. Other high bandwidth products that do not support this complex functionality must attach to such a host unit either directly or via a local peripheral network to achieve interoperability. Examples of computers or products with embedded computers located on the home network 10, functioning as end user devices, include: the network interface units I/O computers performing external network to home network conversion and conditioning; computers, such as the set-top electronics (STE); PC's; workstations; high end printers; and special computers providing gateway/control functions. Other end user devices that can be coupled to the network 10 include video products: digital compressed (MPEG) and uncompressed video equipment; digital video camcorder products; digital video tape recording products and digital tv display products and analog tv display and recording products. Audio products that can be coupled to the network 10 include: digital compressed (MPEG) and uncompressed audio equipment; HIFI stereo; digital audio tape recording products. Other types of products that can connect to the network 10 are data products, such as printers and other peripherals. Still further products that can be controlled through the network 10 include home automation and appliances: central heating/AC, security controller, microwave oven and other kitchen equipment, lighting, sprinkler and other power control.

Certain embodiments of the home network 10 include one or more local peripheral networks 15 that provide local connection for future very high bit rate, motion-JPEG or I-frame-only-MPEG video devices, audio devices, printers and such peripherals. These devices need continuous local digital connection at a high bandwidth, where the data transfer is continuous from, for example, digital camera to digital VCR. Accommodating such devices directly on the internal network 34 would require greater network bandwidth over the entire network 34 than normally needed. Instead, the local peripheral network 15 is normally connected by gateway to the internal network 34 for interoperability. However, in certain other embodiments of the invention, the home network 10 is provided with hardware and software that accommodates the high speed devices so that a local peripheral network 15 is not necessary.

A home automation network 17 is provided for home automation. This home automation network 17 may run on the power line or other low bit rate network for controlling appliances, home security systems, lighting, etc. This spur originates from a control computer 20 located within the home.

An exemplary model of the installation of the home network 10 of the present invention within a house 36 is depicted in FIG. 2. The home network 10 is a long range backbone capable of up to 100 m cable runs, for example, from a switched hub 38 that forms part of the internal network 34. In the exemplary installation depicted in FIG. 2, the entrance unit 30 with its multiple network interface units 32 are located in a utility area of the house, along with the switched hub 38.

Twisted pair cable is run to each room of the house 36 and terminates at a wall socket. Cat-5 twisted pair (for 100 Mbits/s), for example, may be used when doing an installation, as the majority of the cost is labor. For temporary retro-installation, twisted pair cable is small enough that it may be customer fitted under a carpet edge. A user in the home will connect a computer product in a room by plugging the Ethernet port of the computer product to the Ethernet wall socket.

In the embodiment of FIG. 2, the hub 38 is depicted as a separate device, but in other embodiments the hub 38 is integrated into one or more of the network interface units 32. The hub 38 provides the connectivity to all areas of the house and the one or more network interface units 32. Upgrading, expanding both the aggregate bandwidth and connectivity of the internal network 34, is accomplished by additional plugging or changing to a larger hub. The hub will be discussed in more detail later.

The present invention, as shown in FIGS. 1 and 2, separates the functionality of the network interface units 32 from the set-top electronics 40. Conventionally, a set-top box contains a network interface unit whose components are internally connected by a bus to the set-top electronics components. By contrast, however, the present invention provides a separation of the network interface units 32 and the set-top electronics 40, with the internal network 34 interposed therebetween. This arrangement permits multiple set-top electronics to be distributed throughout the home 36 less expensively, since the electronics of a network interface unit do not have to be duplicated for each set-top electronics. Additionally, having separate network interface units 32 coupled to different external networks and to a common internal network 34 frees the homeowner from being forced to receive all programming from a single source, such as the telephone or cable company. The separation also allows the homeowner to add, drop or change services simply by changing one of the network interface units 32, without the need for replacing all of the set-top electronics 40 throughout the home 36.

In certain embodiments, a “master” set-top box is provided with multiple network interface units. However, this embodiment is logically the same as described above, as the network interface units are connected in this embodiment to the internal network, and not by a bus to the set-top electronics.

FIG. 3 is a logical view of the home network 10 of the present invention. As apparent from the diagram, the multi-port switched hub 38 forms the center of the network connections. In certain embodiments, in which inter-packet jitter is adequately controlled, a traditional, commercially available packet switched hub is employed. In other preferred embodiments, such as that depicted in FIG. 3, the switched hub 38 is a combination of networked ports and ports that are direct (circuit) switched for the duration of a session. The direct connected ports (and systems) can be phase locked via the network (coded) clock. To provide this functionality, the switched hub 38 therefore comprises a relatively simple and inexpensive hub 42 and a direct circuit crossbar 44. The hub 42, in certain preferred embodiments, may be a commercially available device, such as Am79C981 manufactured by Advanced Micro Devices, of Sunnyvale, Calif. Details of the direct circuit crossbar 44 will be described later with respect to FIG. 7.

A star topology as defined by Ethernet 10/100base-T is used in conjunction with the switching hub 38. The switching hub 38 provides fan out to most rooms in the house 36. The maximum system bandwidth is a multiple of the wire bit rate ((bit rate×number of ports)/2), for example, 20 ports and 100 Mbits/s bit rate=1 Gb/s aggregate maximum bandwidth.

The switched hub 38 enables special treatment for the heavily asymmetric traffic, e.g., compressed digital video and internet data by directly routing these cases from transmitter to receiver. This traffic is thus separated from the internal network 34 and allows an overall aggregate bandwidth to be limited only by the expandability of the hub 38, although it will remain limited by the 10 Mbits/s per branch. Use of 100base-T technology instead of 10base-T technology will uprate the network if required.

The switching hub's direct synchronous (Manchester or block encoded) connections are used primarily for the transmission of MPEG video where a continuous, high bit rate, long duration connection is required. High bit rate video in compressed form can be as high as 8 Mbits/sec and is needed for live video and high action movies and sports. Low bit-rate video is 1.5 Mbits/sec. According to the present invention, MPEG digital video is retained throughout the network 10. Conversion to real video takes place only at the display device (e.g., television 12) or the set-top electronics 40.

Two separate direct circuits are depicted as examples in FIG. 3. For example, the network interface unit 32 that is coupled to an ISDN network is directly connected through the direct circuit crossbar 44 to the personal computer 20 of the local peripheral network 15. Another, separate direct circuit is provided by the direct circuit crossbar 44 between a different network interface unit 32 (coupled to hybrid fiber coax, for example) and the set-top electronics 40 coupled to the television 12. Those devices that are not directly connected through the direct circuit crossbar 44 remain attached to the hub 42 and are thus networked.

With respect to the switching hub architecture, where a direct point-to-point path is configured, all data traversing this path is provided directly to the end point terminal of the path, even data intended for one or more other terminals. Thus, in certain preferred embodiments, a rule is followed that data multiplexed with the high rate data (typically messaging) must be issued to networked terminals by the end point of the direct path returning such packets to the hub 38. For example, messages sent over the ISDN network that are not intended for a device on the local peripheral network 15 will be returned by the local peripheral network host 20 to the hub 38 for distribution. This rule saves the expense and complication of having a packet router type switched hub, with the demultiplexing distributed at the end point(s) rather than centrally, and works well for asymmetric data flow and local destination, i.e., not subject to layers of switches.

An advantage of directly switched paths is that potential delays in obtaining access to the network 34 (and possibly upsetting the delicate clock reference timing carried in the MPEG stream) are avoided altogether.

The hub 38, in certain preferred embodiments, is required to be “full-duplex aware” meaning that a directly routed path connects only a transmitter terminal “up” path only to a receive terminal “down” path. By contrast, the path down to the transmitter and path up to the receiver are not affected by the direct circuit and would normally be attached to the network, i.e., attached to all the remaining terminal paths connected together.

Specific routing occurs in response to user service requests. Messages are picked up by the hub control and any direct routing changes implemented. Devices not switched from the network connect and no routing is required.

The MPEG clock recovery is performed at the network interface units 32, as described later. With the MPEG clock recovery at the network interface units 32, and the establishment of a direct circuit to the home network destination, jitter in the signal received at the destination (such as the television 12) is substantially eliminated. Direct circuit capability works well for the heavily asymmetric point to point traffic expected in the entertainment (video) home scenario.

For analog only services, e.g., transitional cable TV, this is not considered part of the digital network. For mixed digital/analog services such as hybrid fiber coax (HFC) and newer forms of mixed cable TV, this is considered a transitional state and dealt with as a temporary add-on to the all digital system of the present invention. The signal from the hybrid fiber coax is provided directly to a set-top electronics 40 or to a network interface unit 32/set-top electronics 40 combination. Two ports are required to connect to the home network 10, one for the network interface unit 32 and one for the set-top electronics 40. A bypass is provided in certain preferred embodiments to link the analog signals across to the audio/video circuits of the set-top electronics 40.

The home network 10 is controlled via hand held commander or computer keyboard to software running at the local terminals, such as the personal computers 20, or set-top electronics 40. Control software local to each home terminal manages source availability, source selection, path management by communication with the network interface units 32 and external gateways. The external network protocols are buffered in the network interface units 32 to provide a standard interface to the terminals on the home network 10. FIG. 8 depicts one example of a user interface. In this embodiment, the home network 10 is transparent and the user is only aware of it indirectly from the number of connected services.

FIG. 4 is a block diagram depicting a single network interface unit 32 coupled by the internal network 34 to a single set-top electronics unit 40. The remaining portions of the home network 10, including the switching hub 38, are not shown in FIG. 4 for purposes of illustration and explanation.

The network interface unit 32 has one or more network interface modules 50 that interface the network interface unit 32 to a particular external network. In the example of FIG. 4, the network interface module 50 provides an interface to an external network that carries MPEG video data. The MPEG video data is provided to an internal network interface device 52 that prepares the data for transport over the internal network 34. In certain preferred embodiments, the internal network 34 is an Ethernet network, so that the internal network interface device 52 is an Ethernet interface device.

The architecture of the present invention assumes that for some networks a first stage demultiplexing at the network interface unit 32 is necessary to stay within a definable bandwidth limit (one stream) rather than an arbitrary bandwidth set by the construction of the incoming stream (multiple streams). Making the assumption that MPEG-2 video is being used, there is a demultiplexing from a multiple program transport stream into a single program transport, as defined in the MPEG-2 specification. This is performed by an MPEG transport chip 54, such as the 9110B chip commercially available from C-Cube. (A second stage demultiplexing to separate the video, audio and other data still occurs in the set-top electronics, while decoding is preferably only performed at the display terminal or computer.) With this approach, it is not necessary to send high bandwidth streams throughout the house and the terminals in the home 36 need see only a standardized single program interface. Compression is required for video generated in the home, e.g. security front door camera or video conference camera.

All the external network interfacing, decryption, access control, demultiplexing to a single program stream, etc., is performed by the network interface module 50. Thus, the network interface module 50 buffers the home network hardware and software from the peculiarities of the attached external network. Multiple different programs require multiple network interface crossbar connections whether from one or multiple providers. In certain embodiments, a dual module is provided with two connections to the crossbar, providing two programs received from the same external network.

The MPEG transport chip 54 performs the MPEG clock recovery and provides the recovered 27 MHz clock and the selected program to an internal network connection 56. The 27 MHz clock is received by an MPEG to network synthesizer 58 and converted to a 10 MHz clock, for example, when the internal network 34 is a 10base-T Ethernet network. The 10 MHz clock, as well as the selected program, are provided to a conventional transceiver 60 (such as an Ethernet transceiver) connected to the internal network 34. The synthesizer 58 acts to lock the Ethernet clock to the recovered MPEG clock. When the packet of data is transmitted from the network interface unit 32 to the set-top electronics 40, the set-top electronics 40 is locked to the recovered MPEG data at 27 MHz. At the set-top electronics 40, the 27 Mhz clock is regenerated from the Ethernet 10 MHz clock by another synthesizer.

The data is received in the set-top electronics 40 by a network interface device 62 that includes a network interface 64. The 10 MHz clock recovered by the network interface 64 from the data stream off the network 34 is gated through gate 66 to a network to MPEG synthesizer 68. Gating is needed so that the locking function is performed only when there is a packet of data present. The 10 MHz clock is converted to a 27 MHz clock provided to an MPEG decoder 70 and a video decoder/encoder 72. The selected program is provided by the network interface 64 to the MPEG decoder 70, which decodes the MPEG data and provides it to the video decoder/encoder 72. The data stream is converted by the video encoder 72 to a format (e.g., NTSC or SVideo) suitable for use by a display device, such as a television. The video decoder is for the case (HFC) where there may be an NTSC analog signal to digitize and merge with on-board graphics hardware.

The network 34 in FIG. 4 is depicted schematically, and it should be understood from the previous description that the video data may be placed on the network 34 through the hub 42, but that a direct circuit of the network interface unit 32 and the set-top electronics 40 through the direct circuit crossbar 44 of the network 34 is preferred to provide a jitter free transfer of video data.

FIG. 5 is a more detailed diagram of an exemplary embodiment of the network interface device 62 of the set-top electronics 40 depicted in FIG. 4. The network interface device 62 includes the network synthesizer 68 coupled to a program logic device operating as the gating device 66. The network synthesizer 68 may be implemented by a commercially available chip, such as the MC145151 manufactured by Motorola. The program logic device 66 may be implemented by a commercially available chip, such as the MC7958, also manufactured by Motorola. A voltage controlled crystal oscillator 80 operates at 27 MHz and provides its signal to the program logic device 66, which gates the 10 MHz signal to the synthesizer 68 when there is a received data packet. The synthesizer divides down the 10 MHz and 27 MHz frequencies to a common frequency which is fed into a phase detector of the synthesizer 68. The output of the phase detector of the synthesizer 68 is provided as a control signal to the voltage controlled crystal oscillator 80 to adjust the local frequency up or down to lock to the incoming Ethernet frequency.

The signal informing the program logic device 66 of the receipt of a data packet, and the 10 MHz clock, are provided by a serial interface adapter 82 serving as a receive enable. A commercially available product suitable for the serial interface adapter is Am7992B, manufactured by Advanced Micro Devices.

The data stream is received through a transformer/filter 84, such as one commercially available from Pulse Engineering, the PE68026. Collision information is also received through another transformer/filter 86, which can be the same type of transformer/filter as 84. The received data is provided to a first network transceiver 88, such as a twisted pair Ethernet transceiver plus (Am79C100). The output of the first network transceiver 88 (the received data) is made available to the receive enable 82 and a controller 90. The controller 90 may be a commercially available product, such as the single-chip Ethernet controller Am79C970 (manufactured by Advanced Micro Devices). The controller 90 is coupled to a bus 92, such as a peripheral component interconnect (PCI) bus, for providing the received data from the network 34 to the MPEG decoder 70 of the set-top electronics 40.

A second network transceiver 92 is coupled to the controller 90, and may be implemented by the same type of transceiver as 88. The second network transceiver 92 provides the transmit path for data from the controller 90 to the network 34 through the transformer/filter 84.

Collision information is routed through transformer/filter 86 and the second transceiver 92 to the controller 90.

FIG. 6 is a more detailed diagram of the internal network connection 56, which has an MPEG to network synthesizer 58 that synthesizes the 10 MHz clock from the 27 MHz MPEG clock recovered by the MPEG transport chip 54 (see FIG. 4). A crystal oscillator 96 is coupled to the synthesizer 58 to provide a 10 MHz signal. In certain embodiments, the crystal oscillator 96 is a 20 MHz oscillator, and the frequency generated by the synthesizer is 20 MHz, which is then simply divided to 10 MHz at the receiver (the set-top electronics 40). A commercially available synthesizer is the MC145145-2, manufactured by Motorola.

The 10 MHz clock is provided to a microprocessor interface 98, which serves as interface for a microprocessor 100. The microprocessor interface 98, with the microprocessor 100, form the transceiver 60 that connects to the internal network 34 through a transformer/filter 102. The microprocessor interface 98 may be, for example, a MC68160 chip manufactured by Motorola, and the microprocessor may be a MC68EN360, also manufactured by Motorola. The transformer/filter 102 may be the same type as transformer/filters 84, 86 of FIG. 5.

The separation of the network interface unit 32 from the set-top electronics 40 provides a number of advantages, as described earlier. The functions (responsibilities) of the conventional set-top boxes with integrated network interface units are divided in embodiments of the present invention. For example, in preferred embodiments, the network interface unit 32 is responsible for performing external network specific interfacing, tuning demodulation, and error correction. It provides external network specific video descrambling and encryption/decryption (credit card number, user password, etc.). The network interface unit 32 also provides an external network specific program guide. Additionally, it performs MPEG transport demultiplexing to a single stream and MPEG reference clock recovery. In preferred embodiments of the invention, the network interface unit provides home network Ethernet interfacing and MPEG/Ethernet clock locking. It also provides the software to support the external network and home network protocols for multiple streams and multiple users. The network interface unit also has the software to act as the gateway for the home network and control the buffering of data as necessary.

The set-top electronics 40 essentially acts as an application computer with audio, video, graphic and analog television interface, in preferred embodiments. For example the set-top electronics provides the home network specific interfacing and data buffering as necessary. It provides Ethernet clock/MPEG clock locking in preferred embodiments. The set-top electronics 40 decodes MPEG video and audio to recover digital audio/video. It performs digital to analog conversion for audio and video, and supports commands from an infrared remote control. The set-top electronics 40 provides support for analog video input (NTSC). It interfaces printers, game ports, etc., and supports boot level operating system and is able to down load a full system from an external network. The set-top electronics 40 supports application programs and communications through the network interface units to a network provider and program video server.

FIG. 7 is a block diagram depicting in more detail an exemplary embodiment of the hub 42 and direct circuit crossbar 44 arrangement of the present invention and its connection with a network interface unit 32 and set-top electronics 40. The direct circuit crossbar 44 and 42 selectively provide either a direct circuit between a particular network interface unit 32 and a set-top electronics 40, or a simple network connection through the hub 42 for these units. In FIG. 7, only portions of the network interface unit 32 and the set-top electronics 40 are depicted, for purposes of illustration and explanation.

In preferred embodiments of the present invention, the hub 42 is a relatively simple and inexpensive hub, since it does not include any sort of packet routing switch or store and forward switch. There is no intelligence that examines the traffic and dynamically switches the hub according to the transmit and receive addresses as in hubs that have packet routing switches.

Although only one network interface unit 32 and one set-top electronics 40 are shown directly connected in FIG. 7, any number of directly connected pairs may be connected by the direct circuit crossbar 44, depending on the size of the crossbar 44. The network interface unit 32 and the set-top electronics 40 are each shown with five pin positions or connections, each of the connections being a pair. This coincides with a conventional telephone plug, the telephone RJ45, which has ten pin positions.

The internal network 34 provides the connection between the network interface units 32, the set-top electronics 40 and the direct circuit crossbar 44. In preferred embodiments, the internal network 34 is 10 or 100base-T Ethernet.

The selection of a network connection or a direct circuit between the network interface unit 32 and the set-top electronics 40 is established by a number of switches 108, which are depicted in FIG. 7 with letter suffixes to distinguish them from each other in the following description. In the example of FIG. 7, the network interface unit 32 and the set-top electronics 40 are to be directly connected with one another, with the network interface unit 32 transmitting data to the set-top electronics 40. A microprocessor 110 serves as the controller for the direct circuit crossbar 44 and controls the positions of the switches 108 in response to user commands that require a direct circuit to perform. For example, a user may choose to watch a movie from a video on demand service and therefore makes this selection on a hand-held remote control. The microprocessor 110, in response to this selection, will then change the positions of the switches 108 to establish a direct circuit between the network interface unit 32 that is connected to the external network that carries the video on demand service, and the set-top electronics 40 that is coupled to the television receiver on which the user desires to view the movie.

In this case, switch 108 a is moved to its illustrated position to connect the transmit lines of transceiver 88 of the network interface unit 32 to line 112 of the direct circuit crossbar 44. The transmit lines of transceiver 88 are no longer connected to the network at the Txl port of the hub 42. Similarly, the receive lines of the transceiver 92 of the set-top electronics 40 are connected through switch 108 g to the same line 112 of the direct circuit crossbar 44. With this direct circuit now established, data entering the home through the network interface unit 32 is not broadcast over the network via the hub 42, but instead is provided directly to the set-top electronics 40 at the location where the data will be used.

Although the direct circuit established by the direct circuit crossbar 44 provides an excellent pathway for data from the network interface unit 32 to the set-top electronics 40, it may occur that not all of the data coming into the network interface unit 32 is meant for the set-top electronics 40. For example, it is possible that e-mail is received over this particular network interface unit 32, and the homeowner wants e-mail to be directed to a personal computer, and not to a television. However, there is no connection to the network 34 due to the direct circuit once a direct circuit is established.

To solve this problem, the set-top electronics 40 examines the addresses of the data packets it receives and performs a routing function for data that is not meant for this set-top electronics 40. The data is rerouted by the set-top electronics 40 onto the network 34 through the hub 42. This re-routing by the end point connection (the set-top electronics 40 in this example) avoids the need for the system to use an expensive and complicated router. The set-top electronics 40 has a microprocessor 120 and associated memory 122 to identify and route the data packets back to the network 34.

The direct circuit between the network interface unit 32 and the set-top electronics 40 provides a jitter-free connection for video data, but the re-routing of other data into the network 34 through the hub allows more than one type of data to be carried into the home by the network interface unit 32. Once the direct circuit between a network interface unit 32 and a set-top electronics unit 40 is established, collision detection is required by the set-top electronics 40 to allow it to transmit to the hub 42. The set-top electronics 40 needs to learn of collisions and re-transmit the data to the network 34 if such collisions occur. The network interface unit 32 can be set, in certain embodiments, to disable collisions because they cannot occur on the direct circuit. However, in certain embodiments, in both the network interface unit port and the set-top electronics port (to the network 34 through the crossbar 44), the same collision pair is included for convenience.

In certain preferred embodiments, one of the five pairs of wires is available to provide picture-in-picture capability for the system. For example, the network interface unit 32 may provide a second stream of data through another transceiver 88 a over a second pair of transmit wires onto a separate crossbar connection line 114. The set-top electronics 40, which has another transceiver 88 a also connected to line 114, receives this second stream of data through the direct circuit to provide a picture-in-picture on a television screen. Thus, both pictures may be provided without jitter by separate direct circuits.

In certain preferred embodiments of the present invention, the crossbar switches 108 are implemented by an analog MOS array of transistors, controlled in response to signals from the controller 110. This is exemplary only, however, as other embodiments employ switches of different design, as appreciated by one of ordinary skill in the art.

Although the description of the invention depicts the arrangement with certain logical distinctions of the functionality of various elements, these logical distinctions may be different in other embodiments. For example, the hub 42 is described as connected to the internal network. However, the hub 42 may also be logically considered as part of the internal network, or even forming the network, with the remaining wiring forming means for attaching end terminals to the hub 42. One of ordinary skill in the art, therefore, will appreciate that the logical distinctions depicted and described in the present specification are exemplary only.

The separation of the network interface unit and the set-top electronics according to the present invention provides a relatively inexpensive connection of a multitude of devices to each other within the home, and to the outside world.

Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims. 

1. A method for distributing an MPEG clock over an internal network by recovering an MPEG clock from a stream of data received from an external network, comprising the steps of: recovering an MPEG related clock from a stream of MPEG data received from the external network at a network interface unit; selecting a program from the stream using an MPEG transport chip located within the network interface unit; direct locking a local clock to the recovered MPEG related clock to provide an internal clock for the internal network which is locked to said recovered MPEG related clock; transmitting the MPEG data from the network interface unit over the internal network according to the internal clock; synthesizing the MPEG clock at set-top electronics coupled to the internal network from the MPEG data transmitted over the internal network according to the internal clock.
 2. The method of claim 1, wherein the internal network is an Ethernet network, and the MPEG clock is 27 MHz and the local clock is 10 MHz.
 3. The method of claim 1, wherein the step of synthesizing the MPEG clock includes supplying a frequency synthesizer with the internal clock and with a signal indicating receipt of MPEG data.
 4. The method of claim 1, wherein the step of synthesizing the MPEG clock includes locking the synthesized MPEG clock to data received at the set-top electronics via the internal network only in response to a signal indicating receipt of MPEG data.
 5. A method according to claim 1, wherein said transmitting step comprises the steps of: providing a direct synchronous connection between the network interface unit and the set-top electronics, and avoiding delays in accessing the internal network and upsetting of clock timing included in the received MPEG data stream by using the direct synchronous connection to transmit the MPEG data to the set-top electronics.
 6. A method according to claim 1, wherein the step of synthesizing the MPEG clock includes supplying a frequency synthesizer with the internal clock which is locked to said recovered MPEG related clock, and comprising the further step of using said internal clock to adjust a local oscillator signal corresponding to said MPEG clock thereby providing an output signal from said frequency synthesizer which corresponds to said MPEG clock and is locked to said recovered MPEG related clock.
 7. A method according to claim 3, comprising the further steps of providing said internal clock to the MPEG synthesizing means, providing a local oscillator signal to the MPEG synthesizing means, and adjusting said local oscillator signal in accordance with said internal clock and said signal indicating receipt of the MPEG data, thereby providing an output signal from said MPEG synthesizing means which is locked to said recovered MPEG related clock.
 8. A method according to claim 3, comprising the further steps of using said signal indicating receipt of the MPEG data to gate said internal clock to MPEG synthesizing means when MPEG data is received, providing said gated internal clock to the MPEG synthesizing means, providing a local oscillator signal corresponding to the MPEG clock to the MPEG synthesizing means, and adjusting said local oscillator signal in accordance with said gated internal clock, thereby providing an output signal from said MPEG synthesizing means locked to said internal clock during times when said MPEG data is received.
 9. An arrangement for recovering an MPEG clock from a stream of MPEG data comprising: a network interface unit that receives an MPEG data stream from an external network and transmits MPEG data to predefined set-top electronics; the network interface unit having an MPEG clock recovery circuit for recovering the MPEG clock from the stream of MPEG data, an MPEG transport chip for selecting a program from the stream, and a first frequency synthesizer for direct locking an internal clock to the recovered MPEG clock; said predefined set-top electronics having a second frequency synthesizer for synthesizing the MPEG clock from MPEG data clocked over the internal network according to the internal clock; and wherein the internal network comprises a plurality of set-top electronics, including said predefined set-top electronics, and a switching hub connecting said network interface unit to at least said predefined set-top electronics having said second frequency synthesizer; said switching hub including direct synchronous connections for connecting said network interface unit to said predefined set-top electronics for transmission of said MPEG data from said network interface unit to said predefined set-top electronics for synthesizing said MPEG clock at said predefined set-top electronics; thereby avoiding delays in accessing the network and upsetting of clock reference timing included in said MPEG data stream.
 10. An arrangement according to claim 9, wherein said second frequency synthesizer is connected for receiving the internal clock which is locked to said recovered MPEG clock, and further comprising a local oscillator generating a local oscillator signal corresponding to said MPEG clock and means for adjusting said local oscillator using said internal clock to adjust the local oscillator signal generated thereby, thereby providing an output signal from said second frequency synthesizer which corresponds to said MPEG clock and is locked to said recovered MPEG related clock.
 11. An arrangement according to claim 10, further comprising means for providing to said second frequency synthesizer a signal indicating receipt of the MPEG data over the internal network by said predefined set-top electronics, and means for gating the internal clock to said second frequency synthesizer when MPEG data is received in response to said signal indicating receipt of the MPEG data, thereby providing an output signal from said second frequency synthesizer which is locked to said internal clock during times when said MPEG data is received.
 12. A method for recovering and distributing an MPEG clock from a stream of MPEG data, comprising: recovering an MPEG related clock from a stream of received MPEG data at a network interface unit coupled to an external network; selecting a program from the stream using an MPEG transport chip located within the network interface unit; direct locking a local clock to the recovered MPEG related clock to provide an internal clock; transmitting the MPEG data from the network interface unit to a set-top electronics coupled to the internal network according to the internal clock; and synthesizing the MPEG clock at the set-top electronics coupled to the internal network from the MPEG data and the internal clock.
 13. A method according to claim 12, wherein said transmitting step comprises the steps of: providing a direct synchronous connection between the network interface unit and the set-top electronics, and avoiding delays in accessing the internal network and upsetting of clock timing included in the received MPEG data stream by using the direct synchronous connection to transmit the MPEG data to the set-top electronics. 